#include <android/log.h>
#include <android/native_window.h>
#include <dvr/dvr_api.h>
#include <dvr/dvr_buffer_queue.h>
#include <gtest/gtest.h>
#include <array>
#include <unordered_map>
#include "dvr_api_test.h"
#define LOG_TAG "dvr_buffer_queue-test"
#ifndef ALOGD
#define ALOGD(...) __android_log_print(ANDROID_LOG_DEBUG, LOG_TAG, __VA_ARGS__)
#endif
#ifndef ALOGD_IF
#define ALOGD_IF(cond, ...) \
((__predict_false(cond)) ? ((void)ALOGD(__VA_ARGS__)) : (void)0)
#endif
namespace {
static constexpr uint32_t kBufferWidth = 100;
static constexpr uint32_t kBufferHeight = 1;
static constexpr uint32_t kLayerCount = 1;
static constexpr uint32_t kBufferFormat = AHARDWAREBUFFER_FORMAT_BLOB;
static constexpr uint64_t kBufferUsage = AHARDWAREBUFFER_USAGE_CPU_READ_OFTEN;
static constexpr size_t kQueueCapacity = 3;
class DvrBufferQueueTest : public DvrApiTest {
public:
static void BufferAvailableCallback(void* context) {
DvrBufferQueueTest* thiz = static_cast<DvrBufferQueueTest*>(context);
thiz->HandleBufferAvailable();
}
static void BufferRemovedCallback(DvrReadBuffer* buffer, void* context) {
DvrBufferQueueTest* thiz = static_cast<DvrBufferQueueTest*>(context);
thiz->HandleBufferRemoved(buffer);
}
protected:
void TearDown() override {
if (write_queue_ != nullptr) {
api_.WriteBufferQueueDestroy(write_queue_);
write_queue_ = nullptr;
}
DvrApiTest::TearDown();
}
void HandleBufferAvailable() {
buffer_available_count_ += 1;
ALOGD_IF(TRACE, "Buffer avaiable, count=%d", buffer_available_count_);
}
void HandleBufferRemoved(DvrReadBuffer* buffer) {
buffer_removed_count_ += 1;
ALOGD_IF(TRACE, "Buffer removed, buffer=%p, count=%d", buffer,
buffer_removed_count_);
}
DvrWriteBufferQueue* write_queue_ = nullptr;
int buffer_available_count_{0};
int buffer_removed_count_{0};
};
TEST_F(DvrBufferQueueTest, WriteQueueCreateDestroy) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
/*capacity=*/0, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
api_.WriteBufferQueueDestroy(write_queue_);
write_queue_ = nullptr;
}
TEST_F(DvrBufferQueueTest, WriteQueueGetCapacity) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
size_t capacity = api_.WriteBufferQueueGetCapacity(write_queue_);
ALOGD_IF(TRACE, "TestWrite_QueueGetCapacity, capacity=%zu", capacity);
ASSERT_EQ(kQueueCapacity, capacity);
}
TEST_F(DvrBufferQueueTest, CreateReadQueueFromWriteQueue) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
/*capacity=*/0, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
DvrReadBufferQueue* read_queue = nullptr;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, read_queue);
api_.ReadBufferQueueDestroy(read_queue);
}
TEST_F(DvrBufferQueueTest, CreateReadQueueFromReadQueue) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
/*capacity=*/0, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
DvrReadBufferQueue* read_queue1 = nullptr;
DvrReadBufferQueue* read_queue2 = nullptr;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue1);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, read_queue1);
ret = api_.ReadBufferQueueCreateReadQueue(read_queue1, &read_queue2);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, read_queue2);
ASSERT_NE(read_queue1, read_queue2);
api_.ReadBufferQueueDestroy(read_queue1);
api_.ReadBufferQueueDestroy(read_queue2);
}
TEST_F(DvrBufferQueueTest, GainBuffer) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(ret, 0);
DvrWriteBuffer* wb = nullptr;
EXPECT_FALSE(api_.WriteBufferIsValid(wb));
DvrNativeBufferMetadata meta;
int fence_fd = -1;
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb, &meta,
&fence_fd);
ASSERT_EQ(ret, 0);
EXPECT_EQ(fence_fd, -1);
EXPECT_NE(wb, nullptr);
EXPECT_TRUE(api_.WriteBufferIsValid(wb));
}
TEST_F(DvrBufferQueueTest, AcquirePostGainRelease) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(ret, 0);
DvrReadBufferQueue* read_queue = nullptr;
DvrReadBuffer* rb = nullptr;
DvrWriteBuffer* wb = nullptr;
DvrNativeBufferMetadata meta1;
DvrNativeBufferMetadata meta2;
int fence_fd = -1;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue);
ASSERT_EQ(ret, 0);
ASSERT_NE(read_queue, nullptr);
api_.ReadBufferQueueSetBufferAvailableCallback(
read_queue, &BufferAvailableCallback, this);
// Gain buffer for writing.
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb,
&meta1, &fence_fd);
ASSERT_EQ(ret, 0);
ASSERT_NE(wb, nullptr);
ASSERT_TRUE(api_.WriteBufferIsValid(wb));
ALOGD_IF(TRACE, "TestDequeuePostDequeueRelease, gain buffer %p, fence_fd=%d",
wb, fence_fd);
close(fence_fd);
// Post buffer to the read_queue.
meta1.timestamp = 42;
ret = api_.WriteBufferQueuePostBuffer(write_queue_, wb, &meta1, /*fence=*/-1);
ASSERT_EQ(ret, 0);
ASSERT_FALSE(api_.WriteBufferIsValid(wb));
wb = nullptr;
// Acquire buffer for reading.
ret = api_.ReadBufferQueueAcquireBuffer(read_queue, /*timeout=*/10, &rb,
&meta2, &fence_fd);
ASSERT_EQ(ret, 0);
ASSERT_NE(rb, nullptr);
// Dequeue is successfully, BufferAvailableCallback should be fired once.
ASSERT_EQ(buffer_available_count_, 1);
ASSERT_TRUE(api_.ReadBufferIsValid(rb));
// Metadata should be passed along from producer to consumer properly.
ASSERT_EQ(meta1.timestamp, meta2.timestamp);
ALOGD_IF(TRACE,
"TestDequeuePostDequeueRelease, acquire buffer %p, fence_fd=%d", rb,
fence_fd);
close(fence_fd);
// Release buffer to the write_queue.
ret = api_.ReadBufferQueueReleaseBuffer(read_queue, rb, &meta2,
/*release_fence_fd=*/-1);
ASSERT_EQ(ret, 0);
ASSERT_FALSE(api_.ReadBufferIsValid(rb));
rb = nullptr;
// TODO(b/34387835) Currently buffer allocation has to happen after all queues
// are initialized.
size_t capacity = api_.ReadBufferQueueGetCapacity(read_queue);
ALOGD_IF(TRACE, "TestDequeuePostDequeueRelease, capacity=%zu", capacity);
ASSERT_EQ(kQueueCapacity, capacity);
api_.ReadBufferQueueDestroy(read_queue);
}
TEST_F(DvrBufferQueueTest, GetANativeWindow) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
/*capacity=*/0, /*user_metadata_size=*/0, &write_queue_);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, write_queue_);
ANativeWindow* window = nullptr;
ret = api_.WriteBufferQueueGetANativeWindow(write_queue_, &window);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, window);
uint32_t width = ANativeWindow_getWidth(window);
uint32_t height = ANativeWindow_getHeight(window);
uint32_t format = ANativeWindow_getFormat(window);
ASSERT_EQ(kBufferWidth, width);
ASSERT_EQ(kBufferHeight, height);
ASSERT_EQ(kBufferFormat, format);
}
// Create buffer queue of three buffers and dequeue three buffers out of it.
// Before each dequeue operation, we resize the buffer queue and expect the
// queue always return buffer with desired dimension.
TEST_F(DvrBufferQueueTest, ResizeBuffer) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
int fence_fd = -1;
DvrNativeBufferMetadata meta;
DvrReadBufferQueue* read_queue = nullptr;
DvrWriteBuffer* wb1 = nullptr;
DvrWriteBuffer* wb2 = nullptr;
DvrWriteBuffer* wb3 = nullptr;
AHardwareBuffer* ahb1 = nullptr;
AHardwareBuffer* ahb2 = nullptr;
AHardwareBuffer* ahb3 = nullptr;
AHardwareBuffer_Desc buffer_desc;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, read_queue);
api_.ReadBufferQueueSetBufferRemovedCallback(read_queue,
&BufferRemovedCallback, this);
// Handle all pending events on the read queue.
ret = api_.ReadBufferQueueHandleEvents(read_queue);
ASSERT_EQ(0, ret);
size_t capacity = api_.ReadBufferQueueGetCapacity(read_queue);
ALOGD_IF(TRACE, "TestResizeBuffer, capacity=%zu", capacity);
ASSERT_EQ(kQueueCapacity, capacity);
// Resize before dequeuing.
constexpr uint32_t w1 = 10;
ret = api_.WriteBufferQueueResizeBuffer(write_queue_, w1, kBufferHeight);
ASSERT_EQ(0, ret);
// Gain first buffer for writing. All buffers will be resized.
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb1,
&meta, &fence_fd);
ASSERT_EQ(0, ret);
ASSERT_TRUE(api_.WriteBufferIsValid(wb1));
ALOGD_IF(TRACE, "TestResizeBuffer, gain buffer %p", wb1);
close(fence_fd);
// Check the buffer dimension.
ret = api_.WriteBufferGetAHardwareBuffer(wb1, &ahb1);
ASSERT_EQ(0, ret);
AHardwareBuffer_describe(ahb1, &buffer_desc);
ASSERT_EQ(w1, buffer_desc.width);
ASSERT_EQ(kBufferHeight, buffer_desc.height);
AHardwareBuffer_release(ahb1);
// For the first resize, all buffers are reallocated.
int expected_buffer_removed_count = kQueueCapacity;
ret = api_.ReadBufferQueueHandleEvents(read_queue);
ASSERT_EQ(0, ret);
ASSERT_EQ(expected_buffer_removed_count, buffer_removed_count_);
// Resize the queue. We are testing with blob format, keep height to be 1.
constexpr uint32_t w2 = 20;
ret = api_.WriteBufferQueueResizeBuffer(write_queue_, w2, kBufferHeight);
ASSERT_EQ(0, ret);
// The next buffer we dequeued should have new width.
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb2,
&meta, &fence_fd);
ASSERT_EQ(0, ret);
ASSERT_TRUE(api_.WriteBufferIsValid(wb2));
ALOGD_IF(TRACE, "TestResizeBuffer, gain buffer %p, fence_fd=%d", wb2,
fence_fd);
close(fence_fd);
// Check the buffer dimension, should be new width
ret = api_.WriteBufferGetAHardwareBuffer(wb2, &ahb2);
ASSERT_EQ(0, ret);
AHardwareBuffer_describe(ahb2, &buffer_desc);
ASSERT_EQ(w2, buffer_desc.width);
AHardwareBuffer_release(ahb2);
// For the second resize, all but one buffers are reallocated.
expected_buffer_removed_count += (kQueueCapacity - 1);
ret = api_.ReadBufferQueueHandleEvents(read_queue);
ASSERT_EQ(0, ret);
ASSERT_EQ(expected_buffer_removed_count, buffer_removed_count_);
// Resize the queue for the third time.
constexpr uint32_t w3 = 30;
ret = api_.WriteBufferQueueResizeBuffer(write_queue_, w3, kBufferHeight);
ASSERT_EQ(0, ret);
// The next buffer we dequeued should have new width.
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb3,
&meta, &fence_fd);
ASSERT_EQ(0, ret);
ASSERT_TRUE(api_.WriteBufferIsValid(wb3));
ALOGD_IF(TRACE, "TestResizeBuffer, gain buffer %p, fence_fd=%d", wb3,
fence_fd);
close(fence_fd);
// Check the buffer dimension, should be new width
ret = api_.WriteBufferGetAHardwareBuffer(wb3, &ahb3);
ASSERT_EQ(0, ret);
AHardwareBuffer_describe(ahb3, &buffer_desc);
ASSERT_EQ(w3, buffer_desc.width);
AHardwareBuffer_release(ahb3);
// For the third resize, all but two buffers are reallocated.
expected_buffer_removed_count += (kQueueCapacity - 2);
ret = api_.ReadBufferQueueHandleEvents(read_queue);
ASSERT_EQ(0, ret);
ASSERT_EQ(expected_buffer_removed_count, buffer_removed_count_);
api_.ReadBufferQueueDestroy(read_queue);
}
TEST_F(DvrBufferQueueTest, ReadQueueEventFd) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
DvrReadBufferQueue* read_queue = nullptr;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue);
ASSERT_EQ(0, ret);
ASSERT_NE(nullptr, read_queue);
int event_fd = api_.ReadBufferQueueGetEventFd(read_queue);
ASSERT_GT(event_fd, 0);
}
// Verifies a Dvr{Read,Write}BufferQueue contains the same set of
// Dvr{Read,Write}Buffer(s) during their lifecycles. And for the same buffer_id,
// the corresponding AHardwareBuffer handle stays the same.
TEST_F(DvrBufferQueueTest, StableBufferIdAndHardwareBuffer) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(0, ret);
int fence_fd = -1;
DvrReadBufferQueue* read_queue = nullptr;
EXPECT_EQ(0, api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue));
// Read buffers.
std::array<DvrReadBuffer*, kQueueCapacity> rbs;
// Write buffers.
std::array<DvrWriteBuffer*, kQueueCapacity> wbs;
// Buffer metadata.
std::array<DvrNativeBufferMetadata, kQueueCapacity> metas;
// Hardware buffers for Read buffers.
std::unordered_map<int, AHardwareBuffer*> rhbs;
// Hardware buffers for Write buffers.
std::unordered_map<int, AHardwareBuffer*> whbs;
constexpr int kNumTests = 100;
// This test runs the following operations many many times. Thus we prefer to
// use ASSERT_XXX rather than EXPECT_XXX to avoid spamming the output.
std::function<void(size_t i)> Gain = [&](size_t i) {
int ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/10,
&wbs[i], &metas[i], &fence_fd);
ASSERT_EQ(ret, 0);
ASSERT_LT(fence_fd, 0); // expect invalid fence.
ASSERT_TRUE(api_.WriteBufferIsValid(wbs[i]));
int buffer_id = api_.WriteBufferGetId(wbs[i]);
ASSERT_GT(buffer_id, 0);
AHardwareBuffer* hb = nullptr;
ASSERT_EQ(0, api_.WriteBufferGetAHardwareBuffer(wbs[i], &hb));
auto whb_it = whbs.find(buffer_id);
if (whb_it == whbs.end()) {
// If this is a new buffer id, check that total number of unique
// hardware buffers won't exceed queue capacity.
ASSERT_LT(whbs.size(), kQueueCapacity);
whbs.emplace(buffer_id, hb);
} else {
// If this is a buffer id we have seen before, check that the
// buffer_id maps to the same AHardwareBuffer handle.
ASSERT_EQ(hb, whb_it->second);
}
};
std::function<void(size_t i)> Post = [&](size_t i) {
ASSERT_TRUE(api_.WriteBufferIsValid(wbs[i]));
metas[i].timestamp++;
int ret = api_.WriteBufferQueuePostBuffer(write_queue_, wbs[i], &metas[i],
/*fence=*/-1);
ASSERT_EQ(ret, 0);
};
std::function<void(size_t i)> Acquire = [&](size_t i) {
int ret = api_.ReadBufferQueueAcquireBuffer(read_queue, /*timeout=*/10,
&rbs[i], &metas[i], &fence_fd);
ASSERT_EQ(ret, 0);
ASSERT_LT(fence_fd, 0); // expect invalid fence.
ASSERT_TRUE(api_.ReadBufferIsValid(rbs[i]));
int buffer_id = api_.ReadBufferGetId(rbs[i]);
ASSERT_GT(buffer_id, 0);
AHardwareBuffer* hb = nullptr;
ASSERT_EQ(0, api_.ReadBufferGetAHardwareBuffer(rbs[i], &hb));
auto rhb_it = rhbs.find(buffer_id);
if (rhb_it == rhbs.end()) {
// If this is a new buffer id, check that total number of unique hardware
// buffers won't exceed queue capacity.
ASSERT_LT(rhbs.size(), kQueueCapacity);
rhbs.emplace(buffer_id, hb);
} else {
// If this is a buffer id we have seen before, check that the buffer_id
// maps to the same AHardwareBuffer handle.
ASSERT_EQ(hb, rhb_it->second);
}
};
std::function<void(size_t i)> Release = [&](size_t i) {
ASSERT_TRUE(api_.ReadBufferIsValid(rbs[i]));
int ret = api_.ReadBufferQueueReleaseBuffer(read_queue, rbs[i], &metas[i],
/*release_fence_fd=*/-1);
ASSERT_EQ(ret, 0);
};
// Scenario one:
for (int i = 0; i < kNumTests; i++) {
// Gain all write buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Gain(i));
}
// Post all write buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Post(i));
}
// Acquire all read buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Acquire(i));
}
// Release all read buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Release(i));
}
}
// Scenario two:
for (int i = 0; i < kNumTests; i++) {
// Gain and post all write buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Gain(i));
ASSERT_NO_FATAL_FAILURE(Post(i));
}
// Acquire and release all read buffers.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Acquire(i));
ASSERT_NO_FATAL_FAILURE(Release(i));
}
}
// Scenario three:
for (int i = 0; i < kNumTests; i++) {
// Gain all write buffers then post them in reversed order.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Gain(i));
}
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Post(kQueueCapacity - 1 - i));
}
// Acquire all write buffers then release them in reversed order.
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Acquire(i));
}
for (size_t i = 0; i < kQueueCapacity; i++) {
ASSERT_NO_FATAL_FAILURE(Release(kQueueCapacity - 1 - i));
}
}
}
TEST_F(DvrBufferQueueTest, ConsumerReleaseAfterProducerDestroy) {
int ret = api_.WriteBufferQueueCreate(
kBufferWidth, kBufferHeight, kBufferFormat, kLayerCount, kBufferUsage,
kQueueCapacity, sizeof(DvrNativeBufferMetadata), &write_queue_);
ASSERT_EQ(ret, 0);
DvrReadBufferQueue* read_queue = nullptr;
DvrReadBuffer* rb = nullptr;
DvrWriteBuffer* wb = nullptr;
DvrNativeBufferMetadata meta1;
DvrNativeBufferMetadata meta2;
int fence_fd = -1;
ret = api_.WriteBufferQueueCreateReadQueue(write_queue_, &read_queue);
ASSERT_EQ(ret, 0);
api_.ReadBufferQueueSetBufferAvailableCallback(
read_queue, &BufferAvailableCallback, this);
// Gain buffer for writing.
ret = api_.WriteBufferQueueGainBuffer(write_queue_, /*timeout=*/0, &wb,
&meta1, &fence_fd);
ASSERT_EQ(ret, 0);
close(fence_fd);
// Post buffer to the read_queue.
ret = api_.WriteBufferQueuePostBuffer(write_queue_, wb, &meta1, /*fence=*/-1);
ASSERT_EQ(ret, 0);
wb = nullptr;
// Acquire buffer for reading.
ret = api_.ReadBufferQueueAcquireBuffer(read_queue, /*timeout=*/10, &rb,
&meta2, &fence_fd);
ASSERT_EQ(ret, 0);
close(fence_fd);
// Destroy the write buffer queue and make sure the reader queue is picking
// these events up.
api_.WriteBufferQueueDestroy(write_queue_);
ret = api_.ReadBufferQueueHandleEvents(read_queue);
ASSERT_EQ(0, ret);
// Release buffer to the write_queue.
ret = api_.ReadBufferQueueReleaseBuffer(read_queue, rb, &meta2,
/*release_fence_fd=*/-1);
ASSERT_EQ(ret, 0);
rb = nullptr;
api_.ReadBufferQueueDestroy(read_queue);
}
} // namespace